TY - JOUR
T1 - Controls on Rift Faulting in the North Basin of the Malawi (Nyasa) Rift, East Africa
AU - Shillington, Donna J.
AU - Scholz, Christopher A.
AU - Chindandali, Patrick R.N.
AU - Gaherty, James B.
AU - Accardo, Natalie J.
AU - Onyango, Evans
AU - Ebinger, Cynthia J.
AU - Nyblade, Andrew A.
N1 - Funding Information:
This work was supported by the National Science Foundation Continental Dynamics program through Award EAR‐1110921/1110882/1109302/1109293 and by Lamont‐Doherty Earth Observatory of Columbia University. Accardo's work on this project was partially supported by an NSF graduate fellowship, and Onyango's participation was supported by an IRIS summer undergraduate internship. Additional support for prestack depth migrations was provided by RakGas. We thank Paradigm Geophysical, Landmark Geophysical and IHS Markit (Kingdom Interpretation Software), for providing academic licenses for seismic processing and interpretation software used in this study. This project would not have been possible without the Herculian efforts of the many individuals, governmental agencies, universities, and companies involved in data acquisition. We gratefully acknowledge the captain and crews of the M/V , F/V , and M/V . Equipment and logistical support for this program were provided by Scripps Oceanographic Institution, the Geological Survey of Denmark and Greenland (GEUS) and Aarhus University, the Geological Survey of Canada, Lengkeek Vessel Engineering, Malawi Shipping Company, and Malawi Fisheries Department. We especially wish to thank Richard Ferdinand, Godson Kamihanda, Ernie Aaron, Mark Gibaud, Jack Greenberg, Alcides Pessoa, Martin Rapa, Jack Schelling, Per Trinhammer, and Douglas Wood, without whom acquisition of this unique data set would not have been possible. We thank James Muirhead for discussion and feedback on an earlier version of this manuscript and Luc Lavier, Ake Fagereng, and an anonymous reviewer for constructive comments that greatly improved the manuscript. Seismic reflection data from this study are available through the Marine Geoscience Data System ( http://www.marine‐geo.org/tools/search/entry.php?id=EARS_SEGMeNT ), and lake‐bottom seismometer data can be accessed from the IRIS DMC ( http://ds.iris.edu/ds/nodes/dmc/forms/assembled‐data/?dataset_report_number=16‐010 ). Katundu Ndunduma Chilembwe
Funding Information:
This work was supported by the National Science Foundation Continental Dynamics program through Award EAR-1110921/1110882/1109302/1109293 and by Lamont-Doherty Earth Observatory of Columbia University. Accardo's work on this project was partially supported by an NSF graduate fellowship, and Onyango's participation was supported by an IRIS summer undergraduate internship. Additional support for prestack depth migrations was provided by RakGas. We thank Paradigm Geophysical, Landmark Geophysical and IHS Markit (Kingdom Interpretation Software), for providing academic licenses for seismic processing and interpretation software used in this study. This project would not have been possible without the Herculian efforts of the many individuals, governmental agencies, universities, and companies involved in data acquisition. We gratefully acknowledge the captain and crews of the M/V Katundu, F/V Ndunduma, and M/V Chilembwe. Equipment and logistical support for this program were provided by Scripps Oceanographic Institution, the Geological Survey of Denmark and Greenland (GEUS) and Aarhus University, the Geological Survey of Canada, Lengkeek Vessel Engineering, Malawi Shipping Company, and Malawi Fisheries Department. We especially wish to thank Richard Ferdinand, Godson Kamihanda, Ernie Aaron, Mark Gibaud, Jack Greenberg, Alcides Pessoa, Martin Rapa, Jack Schelling, Per Trinhammer, and Douglas Wood, without whom acquisition of this unique data set would not have been possible. We thank James Muirhead for discussion and feedback on an earlier version of this manuscript and Luc Lavier, Ake Fagereng, and an anonymous reviewer for constructive comments that greatly improved the manuscript. Seismic reflection data from this study are available through the Marine Geoscience Data System (http://www.marine-geo.org/tools/search/entry.php?id=EARS_SEGMeNT), and lake-bottom seismometer data can be accessed from the IRIS DMC (http://ds.iris.edu/ds/nodes/dmc/forms/assembled-data/?dataset_report_number=16-010).
Publisher Copyright:
©2020. The Authors.
PY - 2020/3/1
Y1 - 2020/3/1
N2 - The North Basin of the Malawi Rift is an active, early-stage rift segment that provides the opportunity to quantify cumulative and recent faulting patterns in a young rift, assess contributions of intrarift faults to accommodating rift opening, and examine controls on spatial patterns of faulting. Multichannel seismic reflection data acquired in Lake Malawi (Nyasa) in 2015 together with legacy multichannel seismic data image a system of synthetic intrarift faults within this border-fault-bounded, half-graben basin. A dense wide-angle seismic reflection/refraction dip profile acquired with lake bottom seismometer data constrains sediment velocities that are used to convert fault throws from travel time to depth. Observed extension on intrarift faulting in the northern and central parts of the North Basin is approximately twice what would be predicted for hanging wall flexure, implying that the intrarift faults contribute to basin opening. The cumulative throw on intrarift faults is higher in the northern part of the rift segment than the south and is anticorrelated with throw on the border fault, which is largest in the southern part of the North Basin. This change in faulting coincides with a change in the orientation of the North Basin from a N-S trend in the south to a NNW-SSE trend in the north. We infer that the distribution of extension is influenced by rift orientation with respect to the regional extension direction. Almost all intrarift faults substantially offset late Quaternary synrift sediments, suggesting they are likely active and need to be considered in hazard assessments.
AB - The North Basin of the Malawi Rift is an active, early-stage rift segment that provides the opportunity to quantify cumulative and recent faulting patterns in a young rift, assess contributions of intrarift faults to accommodating rift opening, and examine controls on spatial patterns of faulting. Multichannel seismic reflection data acquired in Lake Malawi (Nyasa) in 2015 together with legacy multichannel seismic data image a system of synthetic intrarift faults within this border-fault-bounded, half-graben basin. A dense wide-angle seismic reflection/refraction dip profile acquired with lake bottom seismometer data constrains sediment velocities that are used to convert fault throws from travel time to depth. Observed extension on intrarift faulting in the northern and central parts of the North Basin is approximately twice what would be predicted for hanging wall flexure, implying that the intrarift faults contribute to basin opening. The cumulative throw on intrarift faults is higher in the northern part of the rift segment than the south and is anticorrelated with throw on the border fault, which is largest in the southern part of the North Basin. This change in faulting coincides with a change in the orientation of the North Basin from a N-S trend in the south to a NNW-SSE trend in the north. We infer that the distribution of extension is influenced by rift orientation with respect to the regional extension direction. Almost all intrarift faults substantially offset late Quaternary synrift sediments, suggesting they are likely active and need to be considered in hazard assessments.
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U2 - 10.1029/2019TC005633
DO - 10.1029/2019TC005633
M3 - Article
AN - SCOPUS:85082394457
SN - 0278-7407
VL - 39
JO - Tectonics
JF - Tectonics
IS - 3
M1 - e2019TC005633
ER -